DE102015201257B3 - Ball screw and associated electromechanical actuator - Google Patents

Abstract

A ball screw (1, 16) having a ball screw nut (4) arranged on a spindle (2) and complementary raceways (3, 5) formed on the spindle (2) and on the ball screw nut (4), in which in a cage ( 6, 17, 24) and at least one spring element (9, 14, 18) are arranged for generating a restoring force, wherein between the cage (6, 17, 24) and the at least one spring element (9, 18) a ball ( 11, 21) is arranged.

Description

The invention relates to a ball screw with a ball screw nut arranged on a spindle and formed on the spindle and on the ball screw nut, complementary raceways, in which housed in a cage balls and at least one spring element for generating a restoring force are arranged.

In contrast to a recirculating ball nut in a ball screw nut no circulation or no deflection of the balls is provided. The balls can only move in both directions of movement until they run against a stop.

Such ball screws are used as a component of an electromechanical actuator. An electric drive motor is coupled either with the spindle or with the ball screw nut, so that the rotational movement generated by the drive motor is converted into a displacement. Such an electromechanical actuator can be used as an electromechanical brake or as a parking brake in a motor vehicle by a displacement of the ball screw nut displaces a piston of a hydraulic brake system, whereby brake pads are pressed against a brake disc.

From the WO 2009/053359 A1 a ball screw is known in which there are spring elements in addition to balls in the raceways. This is to ensure that there is always a rolling path for unrolling the balls. Under load, the balls roll off, with load-free operation, the balls can slip. By several spring elements, which are referred to there as intermediate spring elements, are used, the friction between adjacent balls should be reduced.

Out DE 10 2013 202 099 A1 a ball screw has become known according to the features of the preamble of claim 1, between the cage and the spring element, a rod is arranged.

In the DE 10 2009 012 235 A1 In contrast, a further developed ball screw is proposed, which additionally has a rolling body cage. The cage prevents rolling elements touching each other, accordingly, a deterioration of the efficiency is avoided by frictional forces. Since a spring member is supported on the cage, an end portion of the spring member can move under load between the cage and the race or the ball groove of the spindle or the ball screw nut, resulting in an undesirable change in the spring force.

The invention is therefore based on the object to provide a ball screw, which is designed so that jamming of the end portion of a spring element is excluded.

To solve this problem is inventively provided in a ball screw of the type mentioned that between the cage and the at least one spring element, a ball is arranged.

Unlike in the prior art, the spring element is not directly on the cage, in particular on an edge of the cage in the circumferential direction, instead, a ball is arranged between the cage and the spring element, which prevents the end portion of the spring element in between the Cage and a track formed intermediate space can push. The intermediate space may be formed both between the cage and the raceway formed on the spindle and, alternatively, between the cage and the raceway formed on the ball screw nut. The end portion of the spring element is spring-loaded against the ball, which causes a centering of the spring. This prevents that the end portion of the spring element is displaced under load in an unintended gap, this displacement also reduces the restoring force generated by the spring. Accordingly, the ball provided according to the invention ensures that a constant restoring force is always generated by the spring element, and in addition to the centering of the end section of the spring element, the ball also effects an exact positioning of the end section.

According to a first embodiment of the ball screw according to the invention, it may be provided that the diameter of the arranged between the cage and the at least one spring element ball is chosen so large that it is a supporting ball. In this embodiment, the diameter of the ball is chosen so that it rolls under load between the opposing raceways.

Preferably, this ball is identical to the other balls, which are arranged between the spindle and the ball screw nut.

According to an alternative embodiment of the ball screw according to the invention, it may also be provided that the diameter of the arranged between the cage and the at least one spring element ball is chosen so small that it is not a supporting ball. In this case, the ball carries no axial load, the ball thus does not roll between the raceways. The ball thus preferably has a smaller diameter than the remaining balls arranged between the spindle and the ball screw nut.

It is also within the scope of the invention that the cage has at least one concave contact surface adapted to the outer contour of the ball arranged between the cage and the at least one spring element. This concave bearing surface is formed substantially opposite to the spherical shape, so that the ball and the outer contour of the cage touch each other along a line. The abutment surface of the cage may be formed on an axially extended portion of the cage. The cage may also have a plurality of such contact surfaces for a plurality of balls.

A preferred embodiment of the ball screw according to the invention provides that it has at least two spring elements which are arranged such that they generate mutually oppositely directed restoring forces. Accordingly, a first spring element can be arranged so that it exerts a force on the cage in a first direction of rotation. Another spring element can then be arranged so that it exerts a force on the cage in the opposite direction of rotation. The two spring elements are preferably supported by a ball on the cage. The two abutment surfaces of the cage may be disposed on opposite sides in the circumferential direction of a projection extending axially on the cage. In many applications, the ball screw on a stroke direction in which it is moved under load. In the opposite direction, the so-called Rückhubrichtung, the movement takes place in contrast virtually no load. For such applications can be dispensed with the ball of that spring element, which is associated with the return stroke. Optionally, it is also possible to dispense with a spring element assigned to the return stroke direction.

It is also within the scope of the invention that the ball screw has at least two axially offset from one another arranged spring elements which are arranged such that they generate restoring forces acting in the same direction. In this embodiment, the spring elements are arranged in parallel, whereby a higher total restoring force can be generated. This results in the advantage that the surface pressure is reduced to the individual spring elements. Thus, the risk is reduced that deforms a spring element in an undesirable manner. Preferably, two parallel spring elements may be arranged such that they are arranged in the region of the axial ends of the ball screw nut. Accordingly, the cage at both axial ends corresponding, adapted to the outer contour of the balls bearing surfaces.

The length of a spring element may be in the ball screw according to the invention between half the circumference and approximately three quarters of the circumference of the raceway. A spring element may thus preferably extend over half the circumference of the raceway or over approximately three quarters of the circumference of a (circular) raceway. By determining the length of a spring element, the spring force generated by this can be influenced.

In the ball screw according to the invention, it is particularly preferred that either the raceways are formed in the spindle so that the balls received in the cage are held therein or that the raceways are formed in the ball screw nut so that the balls received in the cage held therein are. If the ball is held in the ball screw nut, there is the advantage that the spindle can be assembled or disassembled, without the supporting balls fall out. In the opposite case, when the ball is held on the spindle, the spindle can be mounted or dismounted with the balls held on the spindle.

With regard to the cage of the ball screw according to the invention, it may be provided that it has either radially inwardly offset or radially outwardly offset ball pockets. When the cage, more specifically its ball pockets, are not at the equator, the balls are either radially inward or radially outward. The radially inwardly or radially outwardly offset ball pockets may also be formed as a profile formed on the cage, which is offset radially inwardly or radially outwardly with respect to the cylindrical cage surface.

In addition, the invention relates to an electromechanical actuator with a ball screw of the type described and an electric drive motor which is coupled to either the spindle or with the ball screw nut. Preferably, the electromechanical actuator is part of an electromechanical brake and / or an electromechanical parking brake.

The invention will be explained below with reference to embodiments with reference to the drawings. The drawings are schematic representations and show:

1 a first embodiment of a ball screw according to the invention in a perspective, partially sectioned view;

2 a perspective view of the cage of in 1 shown ball screw;

3 a side view of the in 2 shown cage,

4 a further embodiment of a ball screw according to the invention in a perspective, partially sectioned view;

5 the cage of in 4 shown ball screw in a side view;

6 a cage of a ball screw according to the invention;

7 another perspective view of the in 6 shown cage; and

8th a modified embodiment of a cage of a ball screw according to the invention.

The in 1 shown ball screw 1 includes a spindle 2 from the in 1 a section is shown. The spindle 2 has raceways 3 on. In addition, the ball screw includes 1 a ball screw nut 4 , which is also referred to as a ball screw nut. The cylindrical ball screw nut 4 has raceways inside 5 on that to the careers 3 the spindle 2 are adjusted so that inside the ball screw nut 4 Balls can be picked up. The ball screw 1 includes a cage 6 through which the rolling elements designed as balls are guided. In 1 you realize that the cage 6 several axially juxtaposed rows of ball pockets 7 has, which are each spaced apart and in each of which a ball can be accommodated.

The cage 6 is made in this case of a steel sheet and designed as a punched and bent part. In the view of 1 one recognizes a thrust running in the axial direction 8th , wherein the abutting free ends of the cage 6 are welded. To avoid plastic deformation of the cage 6 optionally subjected to a heat treatment, depending on the ball screw 1 acting forces.

The ball screw 1 has a first spring element 9 on, designed as a helical compression spring and between the complementary raceways 3 . 5 the spindle 2 and the ball screw nut 4 is included. In the illustrated embodiment, the first spring element extends 9 approximately over half the circumference of the raceways, that is about 180 °. In 1 you realize that there is an end section 10 of the first spring element 9 not directly on the cage 6 but on a ball 11 supported. With its opposite side, the ball is supported 11 on a concave bearing surface 12 of the cage 6 from. The cage 6 has at this point a section extending in the axial direction 13 on, on which the contact surface 12 for the ball 11 is trained. In this embodiment, it is the ball 11 around a supporting ball, that is, the outer diameter is chosen so that they move during a ball screw 1 on the careers 3 . 5 rolls.

This in 1 shown first spring element 9 is assigned to the main load direction. The spring element 9 holds a Wälzweg for unrolling the balls, so that these in a relative movement between the spindle 2 and the ball screw nut 4 roll over and do not slip.

Due to the fact that the end section 10 of the first spring element 9 at the ball 11 is applied, the end portion 10 centered, thereby preventing it from entering a space between the cage 6 and one of the two careers 3 . 5 passes, as is possible with conventional ball screws, in which the end portion of the spring element rests directly on the cage.

The 2 and 3 show the cage 6 , in which 2 a perspective view and 3 is a side view. The cage 6 is shown without balls in the mounted state in the ball pockets 7 are used.

In 1 is a second spring element 14 shown, which is also on the protruding section 13 of the cage 6 supported. However, the second spring element is supported 14 on the opposite side of the contact surface 12 at the section 13 off, leaving the second spring element 14 exerts a force opposite to that by the first spring element 9 directed force is directed. The second spring element 14 is associated with the return stroke, whereas the first spring element 9 associated with the main load direction. The second spring element 14 , which is associated with the return stroke, is exposed to much lower loads compared to the first spring element, therefore, a ball between the end portion 15 of the second spring element 14 omitted. Nor is it for the end section 15 of the second spring element 14 a specially shaped abutment surface is needed as it is on the opposite side for the ball 11 is provided. In certain applications, even on the second spring element 14 be waived.

4 shows a further embodiment of a ball screw 16 , which essentially coincides with the in 1 shown ball screw 1 matches. Identical components will therefore not be explained again in detail at this point. The ball screw 16 comprises a spindle in accordance with the first embodiment 2 with raceways 3 and a ball screw nut 4 with raceways 5 , In the complementary careers 3 . 5 are balls (not shown) taken from a cage 17 are guided. In the cage 17 are the first spring element 9 , the ball 11 and the second spring element 14 recorded between the tracks. Below the first spring element 9 one recognizes an end portion of the second spring element 14 attached to the ball screw nut 4 supported.

Unlike the one in 1 shown ball screw 1 has the in 4 shown ball screw 16 a third spring element 18 on, the at the first spring element 9 opposite axial side of the ball screw nut 4 is arranged. Between an end section 19 of the third spring element 18 and a contact surface 20 of the cage 17 is a ball 21 arranged identical to the ball 11 is. This in 4 concealed opposite end of the third spring element 18 rests on the ball screw nut 4 from. In modified embodiments, this end may also be supported on another element (not shown), for example on a pin or on a pressed-in pane.

In 4 you can see that the two spring elements 9 . 18 are arranged parallel to each other and generate parallel forces. Through the contact surface 20 that like the contact surface 12 is formed, prevents the end portion 19 of the third spring element 18 in a space between the cage 17 and one of the tracks 3 . 5 shifts. By the parallel spring elements 9 . 18 can the total force of the spring elements 9 . 18 is generated, increased and set to a certain value. In other embodiments, a third, parallel spring element may be provided.

The 5 . 6 and 7 show a side view and perspective views of the cage 17 , In 5 you can see the concave system surfaces 12 . 20 for the balls 11 . 21 , In 5 you realize that a contact surface 22 for the second spring element 14 is designed as a straight, axially extending edge, for the second spring element 14 Thus, no concave contact surface is provided. In the 5 . 6 and 7 are each a few supporting balls 23 represented by the cage 17 are guided. The cage 17 has bullet pockets 7 on, concerning the cage 17 offset radially inward. The balls 23 are that way through the cage 17 in the ball screw nut 4 held, so the spindle 2 can be unscrewed without the supporting balls 23 fall out.

In contrast, shows 8th a differently shaped cage 24 that in accordance with the cage 17 circular segment-shaped contact surfaces 12 . 20 for balls 11 . 21 has, each center a spring element. Next to it is the cage 24 the axially formed contact surface 22 on.

Unlike the cage 17 assigns the cage 24 ball bags 25 on, based on the circumferential surface of the cage 24 offset radially outwards. Due to this special design of the ball pockets 25 become the bearing balls 23 from the cage 24 on the spindle 2 held, so the ball screw nut 4 Can be removed without the balls 23 falling off. Due to the radially outwardly offset ball pockets 25 are the balls 23 kept inwardly offset with respect to their equator.

The ball screws 1 . 16 are part of an electromechanical brake, the spindle 2 is coupled with an electric drive motor. The rotation of the drive motor is in a displacement of the ball screw nut 4 converted, whereby a piston is displaced against brake pads, whereby the brake pads are pressed against a brake disc.

LIST OF REFERENCE NUMBERS

1

Ball Screw

2

spindle

3

career

4

Ball screw nut

5

career

6

Cage

7

ball pocket

8th

shock

9

spring element

10

end

11

Bullet

12

contact surface

13

section

14

spring element

15

end

16

Ball Screw

17

Cage

18

spring element

19

end

20

contact surface

21

Bullet

22

contact surface

23

Bullet

24

Cage

25

ball pocket

Claims (10)

Ball screw ( 1 . 16 ) with one on a spindle ( 2 ) ball screw nut ( 4 ) and on the spindle ( 2 ) and on the ball screw nut ( 4 ), complementary careers ( 3 . 5 ), in which in a cage ( 6 . 17 . 24 ) received balls and at least one spring element ( 9 . 14 . 18 ) are arranged for generating a restoring force, characterized in that between the cage ( 6 . 17 . 24 ) and the at least one spring element ( 9 . 18 ) a ball ( 11 . 21 ) is arranged. Ball screw according to claim 1, characterized in that the diameter of the between the cage ( 6 . 17 . 24 ) and the at least one spring element ( 9 ) arranged ball ( 11 . 21 ) is so large that it is a bearing ball. Ball screw according to claim 1, characterized in that the diameter of the arranged between the cage and the at least one spring element ball is chosen so small that it is not a supporting ball. Ball screw according to one of the preceding claims, characterized in that the cage ( 6 . 17 . 24 ) at least one to the outer contour of between the cage ( 6 . 17 . 24 ) and the at least one spring element ( 9 . 18 ) arranged ball ( 11 . 21 ) adapted concave bearing surface ( 12 ) having. Ball screw according to one of the preceding claims, characterized in that it comprises at least two spring elements ( 9 . 14 . 18 ) arranged to generate mutually oppositely directed restoring forces. Ball screw according to one of the preceding claims, characterized in that it comprises at least two axially offset from each other spring elements ( 9 . 18 ) arranged to generate restoring forces acting in the same direction. Ball screw according to one of the preceding claims, characterized in that the length of a spring element ( 9 . 14 . 18 ) between half the circumference and approximately three quarters of the circumference of the raceway ( 3 . 5 ) is. Ball screw according to one of the preceding claims, characterized in that either the raceways ( 3 ) in the spindle ( 2 ) are designed so that in the cage ( 6 . 17 . 24 held balls are held therein or that the raceways ( 5 ) in the ball screw nut ( 4 ) are designed so that in the cage ( 6 . 17 . 24 ) are held therein. Ball screw according to one of the preceding claims, characterized in that the cage ( 6 . 17 . 24 ) either radially inwardly offset or radially outwardly offset ball pockets ( 7 ) having. Electromechanical actuator with a ball screw drive ( 1 . 16 ) according to one of claims 1 to 9 and one either with the spindle ( 2 ) or with the ball screw nut ( 4 ) coupled electric drive motor.

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